KR102283941B1 - Heat pump - Google Patents

Abstract

The present embodiment includes a compressor to which a compressor suction passage and a compressor discharge passage are connected; a cooling/heating switching valve to which the compressor suction flow path and the compressor discharge flow path are connected; an outdoor heat exchanger connected to the heating switching valve and the outdoor heat exchanger by a connection line; an indoor heat exchanger connected to a heating/cooling switching valve and an indoor heat exchanger connecting line; at least one expansion mechanism installed in a heat exchanger connection line connecting the outdoor heat exchanger and the indoor heat exchanger; an outdoor fan for blowing outdoor air to the outdoor heat exchanger; a current sensor for measuring a current value applied to the outdoor fan; a control unit that alternately performs heating operation and defrost operation in heating mode, the control unit rotates the outdoor fan at a set number of revolutions when returning to heating operation after defrosting operation, calculates an average value of current values at a set cycle, The start of the defrost operation is judged using the average value of the first calculated current value after returning to operation and the average value of the current value calculated after the initial calculation as a factor to sample the optimal data that can detect the actual degree of implantation of the outdoor heat exchanger. Since it is possible to determine the actual implantation degree of the outdoor heat exchanger with high accuracy, there is an advantage in that it is possible to determine the optimal start time of the defrosting operation.

Description

heat pump

The present invention relates to a heat pump, and more particularly, to a heat pump having an outdoor fan that blows outdoor air to an outdoor heat exchanger.

A heat pump is a cooling/heating device that transfers a low-temperature heat source to a high temperature or a high-temperature heat source to a low temperature by using the heat or condensation heat of a refrigerant.

A heat pump includes a compressor for compressing a refrigerant, a cooling/heating switching valve for switching between a cooling operation and a heating operation by changing the flow direction of the refrigerant, an outdoor heat exchanger for exchanging the refrigerant with outdoor air, an expansion mechanism for expanding the refrigerant, and a refrigerant A refrigeration cycle including an indoor heat exchanger for exchanging heat with indoor air may be used, and the room may be cooled or heated.

The outdoor heat exchanger of the heat pump may function as an evaporator for exchanging refrigerant with outdoor air during heating operation, and frost may form on the outdoor heat exchanger during heating operation of the heat pump.

In particular, when the outdoor temperature is low and humidity is high, the amount of implantation of the outdoor heat exchanger can be increased. When the amount of implantation of the outdoor heat exchanger is excessive, the heating performance of the heat pump is reduced.

The heat pump may perform a separate defrosting operation in the middle of a heating operation in order to cause frost in the outdoor heat exchanger as described above.

After performing the defrosting operation as described above, the heat pump may return to the heating operation.

When the defrost operation time of the heat pump is too long, the heating operation time is relatively short, and heating performance may be deteriorated.

On the other hand, when the time of the defrosting operation of the heat pump is too short, the heat pump returns to the heating operation in a state in which the outdoor heat exchanger is not sufficiently defrosted.

The heat pump may detect the implantation of the outdoor heat exchanger during the heating operation, and may stop the heating operation and start the defrosting operation when the outdoor heat exchanger is implanted.

The heat pump may include a visual sensor capable of discriminating a color or an optical sensor capable of detecting light in order to detect the conception of the outdoor heat exchanger.

A heat pump having a visual sensor may include a signal transmission unit that transmits an electrical signal according to a color change detected by the visual sensor, and a defrost circuit that removes frost according to a signal transmitted from the signal transmission unit.

A heat pump having an optical sensor may include a light emitting unit irradiating light to the outdoor heat exchanger, and a light receiving unit receiving light reflected from the outdoor heat exchanger after being irradiated from the light emitting unit to the outdoor heat exchanger, and an output voltage output from the light receiving unit It may include a defrosting circuit that removes frost according to the output voltage signal from which the high-frequency noise of the signal is removed.

However, the heat pump including the visual sensor or the optical sensor as described above may be contaminated with the visual sensor or the optical sensor when used for a long period of time.

KR 10-1085691 B1 (Notice on November 22, 2011) KR 10-1375012 B1 (Announced on March 20, 2014) KR 10-2011-0100098 A (released on September 09, 2011)

It is an object of the present invention to provide a heat pump capable of starting a defrosting operation at an optimal defrosting start time by having high reliability of detection of implantation even after long-term use and being able to accurately determine the degree of actual implantation of an outdoor heat exchanger.

A heat pump according to an embodiment of the present invention includes: a compressor to which a compressor suction passage and a compressor discharge passage are connected; a cooling/heating switching valve to which the compressor suction flow path and the compressor discharge flow path are connected; an outdoor heat exchanger connected to a heating/cooling switching valve and an outdoor heat exchanger connecting line; an indoor heat exchanger connected to a heating/cooling switching valve and an indoor heat exchanger connecting line; at least one expansion mechanism disposed between the outdoor heat exchanger and the indoor heat exchanger; an outdoor fan for blowing outdoor air to the outdoor heat exchanger; a current sensor for measuring a current value applied to the outdoor fan; A control unit for alternately performing a defrosting operation and a heating operation in the heating mode is included.

The controller may start the defrosting operation according to the current value of the current sensor.

When returning to the heating operation after the defrosting operation, the control unit may rotate the outdoor fan at a set rotational speed, and may calculate an average current value at a set period.

The control unit may determine the start of the defrosting operation based on the increase rate of the average current value.

When the increase rate of the average current value is equal to or greater than the set increase rate, the control unit may determine the start of the defrosting operation.

The control unit may determine the start of the defrosting operation by using the average value of the first calculated current value and the average value of the current value calculated after the first calculation as a factor.

When the rotation speed of the outdoor fan reaches the set rotation speed, the control unit may calculate an average current value at a set period after the set time elapses.

The control unit may first determine the start of the defrost operation according to the outdoor temperature, the outdoor heat exchanger temperature, the saturation temperature, the upper temperature of the outdoor heat exchanger, the lower temperature of the outdoor heat exchanger, high pressure, and the number of rotations of the outdoor fan. . And, if it is determined as the start of the defrost operation in the first determination and the average value of the current values calculated after the initial calculation is equal to or greater than a set multiple of the average value of the first calculated current values, the start of the defrost operation may be secondarily determined.

The set multiple may be set in the range of 1.1 times to 1.2 times.

According to an embodiment of the present invention, since the start of the defrost operation is determined using the average value of the current value calculated initially and the average value of the current value calculated at the set period after the initial calculation as a factor, the actual degree of implantation of the outdoor heat exchanger can be detected. There is an advantage of being able to determine the optimal start time of defrosting operation because it is possible to sample the optimal data from the outdoor heat exchanger and to determine the actual implantation degree of the outdoor heat exchanger with high accuracy.

In addition, since the current sensor for detecting the amount of implantation can be located other than the flow path of the outdoor air, there is an advantage of high reliability even when used for a long period of time.

In addition, there is an advantage in that it is possible to determine the optimal defrosting operation start time according to the actual amount of implantation of the outdoor heat exchanger regardless of excessive/low refrigerant amount.

In addition, when the rotation speed of the outdoor fan reaches the set number of revolutions, the average value of the current is calculated after waiting for the set time, and the average value of the initial current value is more reliable than when the current value at the time the set number of revolutions is reached without waiting for the set time is used. There are advantages to be increased.

1 is a diagram illustrating a refrigerant flow when a heat pump according to an embodiment of the present invention is in a cooling operation or a defrosting operation;
2 is a diagram illustrating a refrigerant flow when a heat pump according to an embodiment of the present invention is in a heating operation;
3 is a control block diagram of a heat pump according to an embodiment of the present invention;
4 is a graph showing changes in low pressure and high pressure, a compressor frequency, and an outdoor fan rotation speed, respectively, while the heat pump according to an embodiment of the present invention alternately performs a heating operation and a defrosting operation;
5 is a graph illustrating a change in static pressure according to rotation of an outdoor fan of a heat pump according to an embodiment of the present invention and a change in an average value of the current value of the outdoor fan;
6 is a graph showing changes in the average value of the outdoor fan current value according to the outdoor fan rotation speed and the outdoor temperature of the heat pump according to an embodiment of the present invention;
7 is a flowchart illustrating a method for controlling a heat pump according to an embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with drawings.

1 is a diagram illustrating a refrigerant flow when a heat pump according to an embodiment of the present invention is in a cooling operation or a defrosting operation, and FIG. 2 is a diagram illustrating a refrigerant flow when the heat pump according to an embodiment of the present invention is in a heating operation. 3 is a control block diagram of a heat pump according to an embodiment of the present invention.

The heat pump may include a compressor (1), a heating/cooling switching valve (8), an outdoor heat exchanger (10), an indoor heat exchanger (20), at least one expansion mechanism (30, 40), and an outdoor fan (60). there is.

The compressor 1 may be configured as an inverter compressor, and the input frequency may be varied according to the load of the indoor heat exchanger 20 .

A compressor suction passage 2 and a compressor discharge passage 3 may be connected to the compressor 1 .

The heat pump may further include an accumulator 4 installed in the compressor suction line 2 to contain the liquid refrigerant. The compressor suction line (2) includes an accumulator suction line (2A) connected to the cooling/heating switching valve (8) and the accumulator (4), and an accumulator outlet line (2A) connected to the accumulator (4) and the compressor (1). (2B) may be included.

The heat pump may further include an oil separator 5 installed in the compressor discharge line 3 to separate oil from the refrigerant discharged from the compressor 1 and guide it to the compressor suction line 2 . The compressor discharge line (3) connects the oil separator suction line (3A) connected to the compressor (1) and the oil separator (5), and the oil separator outlet line (3B) connected to the oil separator (5) and the air-conditioning switching valve (8). may include

The heat pump may include a high-pressure sensor 6 installed in the compressor discharge line 3 to sense the pressure of the high-temperature and high-pressure refrigerant discharged from the compressor 1 .

In addition, the heat pump may further include a low pressure sensor 7 installed in the compressor suction line 2 to sense the pressure of the refrigerant sucked into the compressor 1 from the cooling/heating switching valve 8 . The heat pump may include a low temperature sensor (not shown) installed in the compressor suction line 2 to detect the temperature of the refrigerant sucked into the compressor 1 from the cooling/heating switching valve 8 .

The cooling switching valve 8 may be connected to the compressor 1 by the compressor suction flow path 2 and the compressor discharge flow path 3 . The cooling/heating switching valve 8 may be connected to the accumulator suction line 2A of the compressor suction line 2 . The cooling/heating switching valve 8 may be connected to the oil separator outlet line 3B of the compressor discharge line 3 .

The cooling/heating switching valve 8 may be connected to the outdoor heat exchanger 10 and the outdoor heat exchanger connecting line 11 . In addition, the cooling and cooling switching valve 8 may be connected to the indoor heat exchanger 20 and the indoor heat exchanger connecting line 21 .

The cooling/heating switching valve 8 guides the refrigerant flowing from the oil separator 5 to the outdoor heat exchanger connection line 11 and connects the indoor heat exchanger as shown in FIG. 1 during cooling or defrosting operation. The refrigerant flowing in the line 21 may be guided to the accumulator 4 .

During the heating operation, the cooling/heating switching valve 8 guides the refrigerant flowing from the oil separator 5 to the indoor heat exchanger connection line 21 and the outdoor heat exchanger connection line 11 as shown in FIG. ) can be guided to the refrigerant flowing in the accumulator (4).

The outdoor heat exchanger 10 may include a refrigerant tube 12 in which a refrigerant passage through which the refrigerant passes is formed. The outdoor heat exchanger 10 may further include a fin 13 coupled to the refrigerant tube 12 .

The outdoor heat exchanger 10 may include a plurality of refrigerant tubes 12 , and the fins 13 may be connected to the plurality of refrigerant tubes 12 .

The outdoor heat exchanger 10 may be connected to the cooling/heating switching valve 8 by the outdoor heat exchanger connection line 11 , and may be connected to the outdoor expansion mechanism 30 by the outdoor expansion mechanism connection line 31 .

The outdoor heat exchanger (10) exchanges heat with outdoor air while the low-temperature and low-pressure refrigerant flowing from the outdoor expansion device (30) through the connection line (31) of the outdoor expansion device passes through a plurality of refrigerant tubes (12) during cooling or defrosting operation. It may be an evaporator that becomes

In the outdoor heat exchanger (10), after being compressed by the compressor (1) during heating operation, the high-temperature and high-pressure refrigerant flowing through the air-conditioning switching valve (8) and the outdoor heat exchanger connection line (11) passes through a plurality of refrigerant tubes (12). It may be a condenser that exchanges heat with outdoor air while doing so.

Meanwhile, the outdoor heat exchanger 10 may include an upper outdoor heat exchange unit 10A and a lower outdoor heat exchange unit 10B.

The upper outdoor heat exchange unit 10A may include at least one upper refrigerant tube positioned relatively above the plurality of refrigerant tubes 12 . In addition, the lower outdoor heat exchange unit 10B may include a lower refrigerant tube located below the upper refrigerant tube among the plurality of refrigerant tubes 12 .

The outdoor heat exchanger 10 may further include a header 15 connected to the upper heat exchange part 10A and the lower heat exchange part 10B by a header tube 14, and the header 15 is an outdoor heat exchanger connection line ( 11) can be connected.

The outdoor heat exchanger 10 may further include a distributor 17 connected to the upper heat exchange part 10A and the lower heat exchange part 10B by a distributor tube 16, and the distributor 16 is an outdoor expansion device connection line ( 31) can be connected.

The indoor heat exchanger 20 may be connected to the cooling/heating switching valve 8 and the indoor heat exchanger connecting line 21 .

One end of the indoor heat exchanger connection line 21 may be connected to the indoor heat exchanger 20 , and the other end may be connected to the cooling/heating switching valve 8 .

At least one expansion mechanism 30 and 40 may be installed in a heat exchanger connection line connecting the outdoor heat exchanger 10 and the indoor heat exchanger 20 .

The at least one expansion device 30 , 40 may include an outdoor expansion device 30 and an indoor expansion device 40 .

The outdoor expansion device 30 may be connected to the outdoor heat exchanger 10 and the outdoor expansion device connecting line 31 . The outdoor expansion mechanism 30 may be configured as an opening degree variable valve (eg, EEV) capable of adjusting the opening degree.

One end of the outdoor expansion device connection line 31 may be connected to the outdoor expansion device 30 , and the other end may be connected to the distributor 16 .

The indoor expansion mechanism 40 may be connected to the indoor heat exchanger 20 by a connection line 41 for the indoor expansion mechanism. In addition, the indoor expansion device 40 may be connected to the outdoor expansion device 30 and the expansion device connecting line 42 .

The indoor expansion mechanism 40 may be configured as an opening degree variable valve (eg, EEV) capable of adjusting the opening degree.

The heat pump may further include an indoor fan 50 for blowing indoor air to the indoor heat exchanger 10 .

In the heat pump, an indoor heat exchanger 20 , an indoor expansion mechanism 40 , and an indoor fan 50 may be disposed in the indoor unit I.

The outdoor fan 60 may blow outdoor air to the outdoor heat exchanger 20 .

The heat pump consists of a compressor (1), an accumulator (4), an oil separator (5), a cooling/heating switching valve (8), an outdoor heat exchanger (10), an outdoor expansion mechanism (30), and an outdoor fan (60). O) can be placed.

The heat pump may include a current sensor 80 that measures a current value applied to the outdoor fan 60 .

The current sensor 80 may be installed in a power line between the outdoor fan 60 and a power supply that supplies power to the heat pump, and may measure the current applied to the outdoor fan 60 . The current sensor 80 may transmit the measured current value to the controller 120 .

The current sensor 80 may be located other than the passage of outdoor air, and may be disposed at a position not contaminated by external foreign substances. The current sensor 80 may be provided together with the controller 120 in the control box of the heat pump. Of course, the current sensor 80 may be accommodated in a separate sensor housing.

Meanwhile, the heat pump may include various sensors for determining its defrosting operation. The heat pump may include an outdoor temperature sensor 90 that measures the temperature of outdoor air. The outdoor temperature sensor 90 may measure the temperature of the outdoor air and transmit it to the controller 120 .

The heat pump may further include an outdoor heat exchanger temperature sensor 92 that measures the temperature of the outdoor heat exchanger 10 .

The outdoor heat exchanger temperature sensor 92 may be installed on one side of the outdoor heat exchanger 10 to measure the temperature of the outdoor heat exchanger 10 , and transmit the measured temperature value to the controller 120 .

The outdoor heat exchanger temperature sensor 92 may be installed in the refrigerant tube 12 or the fin 13 , and may be installed in the distributor tube 16 or the header tube 14 close to the refrigerant tube 12 . The outdoor heat exchanger temperature sensor 92 can measure the temperature of the outdoor heat exchanger 10 to determine the start of the defrost operation or the end of the defrost operation, and is installed at a position with a large amount of implantation among the outdoor heat exchangers 10 it is preferable

The outdoor heat exchanger temperature sensor 92 may be installed in the lower heat exchange unit 10B or may be installed in a distributor or header tube adjacent to the lower heat exchange unit 10B.

The heat pump may further include an upper temperature sensor 94 for measuring the temperature of the upper heat exchange unit 10A.

The upper temperature sensor 94 is installed in the upper heat exchange part 10A, is installed in a header tube connecting the upper heat exchange part 10A and the header 15, or an upper part of the header 15 that is close to the upper heat exchange part 10A. It is possible to install on

In addition, the heat pump may further include a lower temperature sensor 96 for measuring the temperature of the lower heat exchange unit 10B.

The lower temperature sensor 96 is installed in the lower heat exchange part 10B, installed in a header tube connecting the lower heat exchange part 10B and the header 15, or a lower part of the header 15 close to the lower heat exchange part 10B. It is possible to install on

As described above, when the heat pump includes both the upper temperature sensor 94 and the lower temperature sensor 96, the heat pump reflects the respective temperatures of the upper heat exchange unit 10A and the lower heat exchange unit 10B to perform a defrosting operation. can be started or the defrost operation can be terminated.

The upper temperature sensor 94 may measure the temperature of the upper heat exchange unit 10A and transmit it to the control unit 120 , and the lower temperature sensor 96 measures the temperature of the lower heat exchange unit 10B and sends it to the control unit 120 . can be transmitted

The controller 120 may control the heat pump. The controller 120 may be an outdoor unit controller that controls the compressor 1 , the air-conditioning switching valve 8 , the outdoor expansion mechanism 30 , and the outdoor fan 60 . The control unit 120 controls the compressor 1 , the air-conditioning switching valve 8 , the outdoor unit control unit for controlling the outdoor expansion mechanism 30 and the outdoor fan 60 , and the indoor expansion mechanism 40 and the indoor fan 50 . It may include an indoor unit control unit.

The heat pump may further include an input unit for selecting a cooling mode and a heating mode.

The heat pump may drive the compressor 1 in the cooling mode, and may control the cooling/heating switching valve 8 in the cooling mode as shown in FIG. 1 .

The heat pump may drive the compressor 1 in the heating mode, and may alternately perform a heating operation and a defrosting operation. During the heating operation, the heat pump can control the heating/cooling switching valve 8 in the heating mode as shown in FIG. , it can be controlled in the mode of defrost operation.

When the heating mode starts, the control unit 120 may first perform the heating operation (H), as shown in FIG. 6 , and then alternately perform the defrosting operation (D) and the heating operation (H). .

4 is a graph illustrating changes in low pressure and high pressure, a compressor frequency, and an outdoor fan rotation speed, respectively, while the heat pump according to an embodiment of the present invention alternately performs a heating operation and a defrosting operation.

5 is a graph illustrating changes in static pressure and average current values of the outdoor fan according to rotation of the outdoor fan of the heat pump according to an embodiment of the present invention.

And, FIG. 6 is a graph showing changes in the average value of the current value of the outdoor fan according to the rotational speed of the outdoor fan of the heat pump and the outdoor temperature according to an embodiment of the present invention.

When the heating mode is started, the control unit 120 may first perform the heating operation (H).

As shown in FIG. 4 , during the heating operation (H) of the heat pump, the control unit 120 may rotate the outdoor fan 60 at a set rotation speed (SF). The controller 120 may apply a current to the outdoor fan 60 so that the outdoor fan 60 rotates at a set rotation speed SF during the heating operation (H) of the heat pump. When the heating operation (H) is started, the control unit 120 may turn on the outdoor fan 60, and the rotation speed of the outdoor fan 60 may gradually increase (see H1 in FIG. 4 ).

When the outdoor fan 60 reaches the set rotation speed SF, the controller 120 may apply a current to the outdoor fan 60 so that the outdoor fan 60 maintains the set rotation speed SF. ( See H2 in Fig. 4)

In addition, the control unit 120 may vary the input frequency of the compressor 1 as shown in FIG. 4 during the heating operation (H) of the heat pump. When the heating operation (H) is started, the control unit 120 may start the compressor 1 and may increase the input frequency of the compressor 1 in stages. (See H1 and H2 in Fig. 4)

The control unit 120 may stop the heating operation (H) and start the defrosting operation (D) when the start condition of the defrosting operation (D) is reached in the middle of the heating operation (H).

When the start condition of the defrost operation (D) is reached during the heating operation (H), the control unit 120 does not turn off the outdoor fan 60 that was being driven at the set rotation speed (SF) during the heating operation (H), and the outdoor fan (60) can be continuously maintained at the set rotation speed (SF), and the outdoor fan (60) can be turned off while the defrosting operation (D) is in progress.

That is, the control unit 120 may stop the outdoor fan 60 while the defrosting operation (D) is in progress. The defrosting operation (D) is an initial defrosting operation (D1) in which the outdoor heat exchanger (10) is defrosted while the outdoor fan (60) is rotated at a set rotation speed (SF), and an outdoor fan (60) after the initial defrosting operation (D1) ) can be divided into a late defrost operation (D2) in which the outdoor heat exchanger 10 is defrosted in an off state.

And, when the start condition of the defrosting operation (D) is reached in the middle of the heating operation (H), the control unit 120 does not turn off the compressor 1 and drives the compressor 1 at an input frequency lower than that of the heating operation (H). It can be done (refer to D in Fig. 4).

In the middle of the defrost operation (D), when the defrost operation end condition is reached, the control unit 120 ends the defrost operation (D) and returns the heating operation (H), and in this case, the defrost operation (D) was turned off The outdoor fan 60 is rotated at the set rotation speed again, and the input frequency of the compressor 1 can be changed higher than during the defrost operation (D) without turning off the compressor 1 that was being driven during the defrosting operation.

On the other hand, when the outdoor fan 60 is controlled to maintain the set rotation speed SF during the heating operation (H), if the amount of implantation of the outdoor heat exchanger 10 is large, before the outdoor heat exchanger 10 in the air flow direction, A static pressure is generated by the subsequent pressure loss, and when the static pressure is generated, the controller 120 may increase the current of the outdoor fan 60 so that the outdoor fan 60 can maintain the set rotation speed SF.

That is, when the static pressure of the outdoor fan 60 increases due to an increase in the amount of implantation at the same rotational speed, the current may increase.

Conversely, when the outdoor fan 60 is controlled to maintain the set rotation speed SF during the heating operation H, if the amount of implantation of the outdoor heat exchanger 10 is small, the static pressure is reduced, and the control unit 120 is The current of the outdoor fan 60 may be reduced so that the fan 60 may maintain the set rotation speed SF.

During the heating operation (H), the current flowing through the outdoor fan 60 may be increased by the amount of implantation of the outdoor heat exchanger 10 , and the control unit 120 exchanges outdoor heat by the current value flowing through the outdoor fan 60 . It is possible to determine the degree of implantation of the device (10).

The current value of the outdoor fan 60 is the static pressure ^K can be proportional to Here, K may be 1.5.

Referring to FIG. 5 for the current value of the outdoor fan 60, it can be seen that the average value of the current value of the outdoor fan 60 is increased so that the static pressure of the outdoor fan 60 can be increased.

The control unit 120 may start the defrosting operation according to the current value of the current sensor 80 during the heating operation (H).

The control unit 120 may determine the increase rate of the average current value of the outdoor fan 60 over time during the heating operation (H), and determine whether to start the defrosting operation using the increase rate of the average current value as a factor can do.

5 is a graph showing the average change of current values according to the static pressure change of two different types of outdoor fans, and is a graph showing changes in the average value of a plurality of current values (eg, 60 current values).

OF1 of FIG. 5 is an example in which the average current value of the outdoor fan is rapidly increased as the static pressure increases, and OF2 of FIG. 4 shows the average current value of the outdoor fan 60 as the static pressure increases. This is an example of a more gently increasing case.

Referring to FIG. 5 , the static pressure of each of the two outdoor fans of different types may be increased from 100Pa to 150Pa. In this case, the average difference between the current values of OF1 in FIG. 5 is 1.2A, and the average value of the current values of OF2 in FIG. 4 . The car can be 1.8. However, an increase rate of the average current value of each of OF1 and OF2 of FIG. 5 may be 80%.

As in the present embodiment, when the start of the defrosting operation is determined based on the increase rate of the average current value, whether the defrosting operation is started or not can be universally determined even if the types or sizes of the outdoor fans are different.

As described above, when the increase rate of the average current value is used as a determining factor for the defrosting operation (D), the outdoor heat exchanger 10 is not sufficiently conceived, it is possible to minimize the start of the defrost operation, and the outdoor heat exchanger ( 10) has been sufficiently implanted, it is possible to minimize the failure of the defrosting operation to start, and it is possible to more accurately detect whether the outdoor heat exchanger 10 is implanted.

That is, the controller 120 may determine the start of the defrosting operation based on the increase rate of the average current value. When the increase rate of the average current value is equal to or greater than the set increase rate, the control unit 120 may determine the start of the defrosting operation.

The determination of the start of the defrost operation according to the increase rate of the average current value will be described in detail as follows.

The control unit 120 of this embodiment may calculate an average current value (hereinafter referred to as a 'reference average value') when the outdoor heat exchanger 10 is not implanted, and the average current value is the average value of the current value after conception and It can be used as a benchmark for comparison.

In addition, the control unit 120 may calculate the reference average value differently depending on the outdoor temperature during each heating operation (H) without setting the reference average value as a preset fixed value.

The control unit 120 may calculate a reference average value for each heating operation (H), and may be used as a reference to determine the start time of the defrosting operation (D) performed after the currently ongoing heating operation (H).

Since the air density is different depending on the outdoor temperature, the reference average value may be calculated for each heating operation in consideration of the change in the outdoor temperature (ie, the change in air density).

OF3 of FIG. 6 is a graph showing the change in the average current value according to the set rotational speed of the outdoor fan when the outdoor temperature is -5°C, and OF4 of FIG. 6 is the set number of rotations of the outdoor fan when the outdoor temperature is 7°C is a graph showing the change in the average current value according to

6, when the outdoor fan 60 has the same rotation speed, the average value of the current flowing through the outdoor fan 60 varies depending on the outdoor temperature, and the lower the outdoor temperature, the higher the density of air increases It can be seen that the average value increases.

That is, in this embodiment, the reference average value is calculated for every heating operation (H), and the actual implantation degree in consideration of the change in the outdoor temperature can be determined with high accuracy.

On the other hand, in the first defrosting operation performed after the initial heating operation according to the start of the heating mode, the controller 120 preferably does not consider the increase rate of the average current value as described above in order to start the defrost operation more quickly.

That is, it is preferable that the determination of the start of the defrost operation according to the increase rate of the average current value is considered from the second defrost operation in the heating mode.

In the heating mode, if the average current value is used from the second defrost operation after the first defrost operation, the first defrost operation can not be delayed after the heating mode starts, and the defrost operation can be started reliably from the second defrost operation. There is an advantage.

When returning to the heating operation (H) after the defrost operation (D), the control unit 120 rotates the outdoor fan 60 at the set rotation speed (SF), and calculates the average value of the current values in the set period (F). there is. Then, the control unit 120 may determine the start of the defrosting operation (D) using the first calculated average current value (Average A) and the average value (Average B) of the current values calculated after the initial calculation as factors.

Here, the first calculated average current value (Average A) may be the first calculated current value average value for each heating operation after the heat pump returns from the defrosting operation (D) to the heating operation (H), and as the reference average value can be decided.

And, the average current value (Average B) calculated with the set period (F) after the initial calculation is the average current value calculated after the first calculated average current value (Average A), and the idea of the outdoor heat exchanger (10) is It may be a value that gradually increases as the process progresses.

On the other hand, when the rotation speed of the outdoor fan 60 reaches the set rotation speed (SF), the control unit 120 calculates the average current value (Average A, Average B) in the set period (F) after the set time (T) elapses. can

Here, the set time T may be a time for delaying the calculation start time of the reference average value in order to secure the reliability of the reference average value (ie, the initially calculated average current value Average A). The set time T may be a preset time such as 1 minute or 2 minutes.

In addition, the setting period is a period for calculating the average current values (Average A, Average B), and the setting period may be a preset period such as 2 minutes.

The control unit 120 does not use the current value for a set time from the time when the rotation speed of the outdoor fan 60 is increased and the rotation speed of the outdoor fan 60 reaches the set rotation speed SF to calculate the average current value, After the rotation speed of the outdoor fan 60 reaches the set rotation speed SF, the average current values (Average A, Average B) may be calculated at a set period from a time point when a set time has elapsed.

The controller 120 may determine an average current value first calculated among the average current values calculated in this way as the reference average value Average A. In addition, the controller 120 may compare the average current values calculated after the first among the average current values calculated in the set period (Average A, Average B) with the reference average value (Average A).

For example, when the set time is set to 1 minute and the set period is set to 2 minutes, the control unit 120 controls for 1 minute from the time when the rotation speed of the outdoor fan 60 reaches the set rotation speed SF. Without using the current value of the current value to calculate the average current value, the average current values (Average A, Average B ) can be calculated.

The controller 120 may determine, as the reference average value Average A, the first average current value calculated among the average current values calculated in the 2-minute period (Average A, Average B).

The controller 120 may compare the average current values calculated after the first among the average current values calculated at a 2-minute period (Average A, Average B) with the reference average value (Average A).

If the average value (Average B) of the current values calculated at the set period after the initial calculation as described above is greater than or equal to a set multiple of the average value of the current values calculated initially (Average A), the start of the defrost operation can be determined. .

Here, the set multiple may be a multiple in which the increase rate of the average current value is equal to or greater than the set increase rate. The set multiple may be set in the range of 1.1 times to 1.2 times.

For example, when the set multiple is 1.15, if the average value (Average B) of the current values calculated at the set period after the initial calculation is 1.15 times or more of the first calculated average value (Average A), the control unit 120 controls the defrost operation can be judged by the initiation of Conversely, if the average value (Average B) of the current values calculated in the set period after the initial calculation is less than 1.15 times the average value of the first current values (Average A), it can be determined that the increase rate of the average value of the current value is low, and the defrost operation can wait for the initiation of

As the time of the heating operation (H) gradually elapses, the average value (Average B) of the current values calculated at a set period after the initial calculation may be equal to or greater than a set multiple of the average value of the current values calculated first (Average A), and the control unit 120 ) may stop the heating operation (H) and start the defrosting operation (D).

On the other hand, the control unit 120 first determines the defrost operation from other factors except for the factor of the average current value, and when it is first determined as the start of the defrost operation according to these other factors, the factor of the average value of the current value as described above It is possible to start the defrost operation (D) when the start of the defrost operation is secondarily determined by the furnace, and both the first determination and the second determination are satisfied.

Hereinafter, the first determination and the second determination of the start of the defrost operation will be described in detail as follows.

7 is a flowchart illustrating a method for controlling a heat pump according to an embodiment of the present invention.

During the heating operation, the controller 120 controls the outdoor temperature (Tari), the outdoor heat exchanger temperature (T_hex), the saturation temperature (T_dew), the upper temperature (T_hi) of the outdoor heat exchanger, and the lower temperature (T_low) of the outdoor heat exchanger. , the high pressure (P_hi), and the rotation speed of the outdoor fan (Fan RPM), the start of the defrost operation may be primarily determined. (S1) (S2)

The outdoor temperature Tair detected by the outdoor temperature sensor 90 may be transmitted to the control unit 120 , and the temperature T_hex of the outdoor heat exchanger detected by the outdoor heat exchanger temperature sensor 92 is transmitted to the control unit 120 . can be transmitted.

Then, the low pressure sensed by the low pressure sensor 7 may be transmitted to the control unit 120, and the control unit 120 calculates the saturation temperature by inputting the low pressure detected by the low pressure sensor 7 into a predetermined equation or table. can do.

The upper temperature T_hi of the outdoor heat exchanger detected by the upper temperature sensor 94 may be transmitted to the controller 120, and the lower temperature T_low of the outdoor heat exchanger detected by the lower temperature sensor 96 is may be transmitted to the controller 120 .

The high pressure sensor 6 may transmit the sensed high pressure to the controller 120 .

Various examples are applicable to the first determination of the start of the defrost operation.

For example, during the heating operation, the control unit 120 controls the outdoor temperature (Tari), the outdoor heat exchanger temperature (T_hex), the saturation temperature (T_dew), the upper temperature (T_hi) of the outdoor heat exchanger, and the lower temperature (T_hi) of the outdoor heat exchanger ( T_low), high pressure (P_hi), and the rotation speed of the outdoor fan (Fan RPM) can be considered together.

The controller 120 may first determine the start of the defrosting operation under different conditions according to the temperature difference range between the outdoor temperature Tair and the outdoor heat exchanger T_hex.

If the temperature difference between the outdoor temperature (Tair) and the outdoor heat exchanger (T_hex) is greater than 10°C and less than or equal to 15°C, the control unit 120 controls the difference between the outdoor temperature (Tair) and the upper temperature of the outdoor heat exchanger (T_hi) or the outdoor temperature (Tair) and at least one of the difference between the lower temperature (T_low) of the outdoor heat exchanger is greater than 7℃, the temperature of the outdoor heat exchanger (T_hex) is less than -5℃, the high pressure (P_hi) is 2300kPa or less, or the rate of change of the saturation temperature is 2 If it exceeds ℃, it can be determined primarily as the start of the defrost operation.

If the temperature difference between the outdoor temperature (Tair) and the outdoor heat exchanger (T_hex) is greater than 10°C and less than or equal to 15°C, the controller 120 controls the difference between the outdoor temperature (Tair) and the upper temperature of the outdoor heat exchanger (T_hi) or the outdoor temperature (Tair) and outdoor heat exchanger lower temperature (T_low)) is 7℃ or less, outdoor heat exchanger temperature (T_hex) is -5℃ or more, high pressure (P_hi) is more than 2300kPa, or the rate of change of saturation temperature is 2℃ or less In this case, the current heating operation may be continued without the first determination as the start of the defrosting operation.

When the temperature difference between the outdoor temperature (Tair) and the outdoor heat exchanger (T_hex) exceeds 15 °C, the control unit 120 is the maximum rotation speed of the outdoor fan, and the temperature of the outdoor heat exchanger (T_hex) is less than 0 °C, defrost operation The first judgment can be made by the initiation of

When the temperature difference between the outdoor temperature (Tair) and the outdoor heat exchanger (T_hex) exceeds 15°C, the control unit 120 performs a defrost operation if the outdoor fan is less than the maximum rotation speed or the temperature of the outdoor heat exchanger (T_hex) is 0°C or higher. It is possible to continue the current heating operation without making a primary judgment by the start of

On the other hand, when the temperature difference between the outdoor temperature (Tair) and the outdoor heat exchanger (T_hex) is 10° C. or less, the controller 120 may continue the current heating operation without first determining the start of the defrosting operation.

The control unit 120 determines that the defrost operation is started in the first determination as described above, and the average value (Average B) of the current values calculated at the set period after the initial calculation is the first calculated average value (Average A) is more than the set multiple In this case, it is possible to make a secondary determination as the start of the defrost operation. (S3) (S4)

After the first determination is made as the start of the defrosting operation, the control unit 120 may determine the start of the defrosting operation as the start of the defrosting operation when it is determined secondly as the start of the defrosting operation (S5).

When it is finally determined that the defrosting operation is started, the control unit 120 may control the cooling/heating switching valve 8 in the mode of the defrosting operation as shown in FIG. 1 , and may perform the defrosting operation.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains.

Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments.

The protection scope of the present invention should be construed by the following claims, and all technical ideas within the equivalent range should be construed as being included in the scope of the present invention.

One; Compressor 2: Compressor suction path
3: Compressor discharge flow path 8: Heating and cooling switching valve
10: outdoor heat exchanger 20: indoor heat exchanger
30, 40: expansion mechanism 60: outdoor fan
80: current sensor 120: control unit
D: Defrost operation H: Heat operation

Claims (4)

a compressor to which the compressor suction passage and the compressor discharge passage are connected;
a cooling/heating switching valve to which the compressor suction flow path and the compressor discharge flow path are connected;
an outdoor heat exchanger connected to the air-conditioning switching valve and the outdoor heat exchanger through a connection line;
an indoor heat exchanger connected to the air-conditioning switching valve and the indoor heat exchanger through a connection line;
at least one expansion mechanism disposed between the outdoor heat exchanger and the indoor heat exchanger;
an outdoor fan for blowing outdoor air to the outdoor heat exchanger;
a current sensor for measuring a current value applied to the outdoor fan;
Including a control unit that alternately performs heating operation and defrost operation in heating mode,
the control unit
When returning to heating operation after defrosting operation,
Rotating the outdoor fan at a set number of revolutions,
Calculates the average value of the current value at the set period,
A heat pump that determines the start of the defrosting operation by using the average value of the current value initially calculated after returning to the heating operation and the average value of the current value calculated after the initial calculation as a factor. The method of claim 1,
The control unit calculates an average current value at the set period after a set time has elapsed when the rotation speed of the outdoor fan reaches a set rotation speed. 3. The method of claim 2,
The control unit first initiates the defrosting operation according to at least one of an outdoor temperature, an outdoor heat exchanger temperature, a saturation temperature, an upper temperature of the outdoor heat exchanger, a lower temperature of the outdoor heat exchanger, high pressure, and the rotation speed of the outdoor fan. judge,
If it is determined that the start of the defrost operation in the first determination and the average current value calculated in the set period after the first calculation is greater than or equal to a set multiple of the first calculated average current value, the heat pump is secondarily determined as the start of the defrosting operation. 4. The method of claim 3,
The set multiple is a heat pump set in the range of 1.1 times to 1.2 times.

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